Methods and apparatus for production of natural l-menthol

ABSTRACT

Embodiments are provided that provide for efficient production of highly pure natural I-menthol. In some embodiments, a method for preparing natural I-menthol involves providing crude mentha oil in a crystallizer and gradually reducing the temperature of the crystallizer in a step-wise manner, thereby producing highly pure crystals in less than two weeks. The methods disclosed herein are suitable for pharmaceutical GMP.

CROSS-REFERENCING TO RELATED APPLICATIONS

The present application is a divisional of U.S. application Ser. No.13/148,929, filed Aug. 10, 2011, which in turn, claims the benefit ofpriority to U.S. Provisional Application No. 61/153,258, filed Feb. 17,2009, both of which are hereby incorporated by reference in theirentirety.

FIELD

The present disclosure relates to a method and apparatus for theproduction of I-menthol.

INTRODUCTION

Menthol, particularly I-menthol, is an important substance widely usedin the field of, for example, food additives, drug components,cosmetics, fragrances and medicines. I-Menthol is the main component ofthe mentha oils from Mentha arvensis and Mentha piperita. I-Menthol isgenerally obtained from the crude mentha oil by crystallization.Depending on the crystallization method and the starting material, thecrystals differ in terms of taste, size and shape. Residual liquidmentha oil adhering to the menthol crystals obtained from mentha oilsaffects the sensory profile of the crystals. I-Menthol hasconventionally been used as a flavor for food, including sweets and oralrefreshments such as, for example, chewing gum, candy, cigarettes andthe like. The presence of trace amounts of impurities can detrimentallyaffect the quality and flavor of I-menthol, and therefore, processes forproducing highly pure I-menthol have been of interest for a long time.

I-Menthol is commercially available in solid forms such as powders,crystals, solidified distillate, flakes and pressed articles. Ingeneral, natural I-menthol is purified from crude mentha oil, such as byrecrystallization of oil from Mentha arvensis. Such I-menthol productionmethods, however, involve production times of greater than two weeks toa month. In these previous I-menthol production methods, native crudementha oil cannot be used directly for the crystallization process.Rather, the methods require an initial crystallization to prepare crudeI-menthol from the crude mentha oil, and then a recrystallization stepto prepare purified I-menthol product. In addition, previously knownmethods for producing I-menthol have involved significant manual laborand handling of the process materials. Because of the necessity ofhandling the mentha oil and the resulting I-menthol crystals, adaptationof these I-menthol production processes to Good Manufacturing Practice(GMP) regulation is likely to be difficult.

SUMMARY

The present teachings provide, among other things, methods and apparatusfor production of highly pure natural I-menthol.

Various embodiments of a method of the present teachings comprisecrystallizing I-menthol from crude mentha oil by gradual cooling in acontainer; and purifying the resulting crystals in the same container.

Some embodiments disclosed herein include a method for purifyingI-menthol, comprising providing crude mentha oil in a crystallizer;crystallizing I-menthol from the crude mentha oil by gradually reducingtemperature in the crystallizer; passing a fluid over the I-mentholcrystals to remove residual oil and impurities, wherein purifiedI-menthol crystals of at least 98% purity by weight are obtained;melting the purified I-menthol crystals to remove I-menthol from thecrystallizer as a melt; and cooling the melt into a dried, solidI-menthol product, wherein the method is performed in a closed systemwithout human contact with the crude mentha oil or the I-menthol.

In some embodiments, the crude mentha oil is of plant origin.

In some embodiments, the I-menthol product has a purity of at least 99%by weight. In some embodiments, the I-menthol product has a purity of atleast 99.4% by weight.

In some embodiments, the crude mentha oil comprises I-menthol in therange of about 30% to about 95% by weight. In some embodiments, theI-menthol concentration in the crude mentha oil is in the range of about50% to about 90% by weight. In some embodiments, the crude mentha oilcontains less than about 30% by weight of an organic solvent. In someembodiments, the crude mentha oil is substantially free of added organicsolvent.

In some embodiments, the temperature in the crystallizer is graduallyreduced to 41° C. In some embodiments, the temperature in thecrystallizer is gradually reduced to between about −30° C. to about 30°C.

In some embodiments, the method further comprises comminuting the solidI-menthol product into particulate. In some embodiments, the particulateare pellets.

In some embodiments, the method further comprises extruding the solidI-menthol product, wherein said comminuting the solid I-menthol productis cutting the extruded solid I-menthol product. In some embodiments,the pellets are formed using a pelletizer fluidly coupled to thecrystallizer.

In some embodiments, the method further comprises introducing seedcrystals of I-menthol into the crystallizer to aid crystallizingI-menthol. In some embodiments, introducing seed crystals of I-mentholcomprises adding pre-formed seed crystals of I-menthol.

In some embodiments, said introducing seed crystals of I-mentholcomprises rapidly cooling a portion of the crude mentha oil to form theI-menthol seed crystals. In some embodiments, said rapidly cooling aportion of crude mentha oil comprises exposing the portion of crudementha oil to a surface having a temperature of no more than about 10°C. In some embodiments, the surface has a temperature in the range ofabout 0° C. to about 20° C.

In some embodiments, the method further comprises removing residual oilsand impurities while gradually elevating the temperature in thecrystallizer.

In some embodiments, the method further comprises applying reduced orincreased pressure to aid removing residual oils and impurities whilegradually elevating the temperature in the crystallizer. In someembodiments, the I-menthol crystals are gradually elevated to atemperature in the range of about 35° C. to about 40° C. In someembodiments, the fluid is a gas. In some embodiments, the gas isselected from the group consisting of air, N2, an inert gas andcombinations thereof.

In some embodiments, the purified I-menthol crystals are obtained bycrystallizing the crude mentha oil only once.

Some embodiments disclosed herein include a system for purifyingI-menthol, comprising a crystallizer containing crude mentha oil ofplant origin; a stripping system adapted to pass a gas through thecrystallizer; an automated process control system comprising a processorprogrammed to: initiate reduction of a temperature in the crystallizerin order to reduce the temperature of the crude mentha oil from atemperature at which the crude mentha oil is a liquid to a temperaturebelow 30° C. in a gradual manner over a period of at least 8 hours tocause I-menthol crystals to form in the crystallizer; activate thestripping system in order to pass the gas over the crystals in thecrystallizer to remove liquid from the crystals; and initiate heating ofthe crystallizer in order to melt the crystals, and a conduit configuredto receive melted I-menthol from the crystallizer, wherein thecrystallizer and the conduit together comprise a closed system thatprevents contact between the content of the closed system and outsidecontaminants.

In some embodiments, the crude mentha oil comprises I-menthol in therange of about 30% to about 95% by weight. In some embodiments, theI-menthol concentration in the crude mentha oil is in the range of about30% to about 50% by weight.

In some embodiments, the crystallizer comprises a plurality of coolingplates and/or cooling coils. In some embodiments, the automated processcontrol system independently controls the temperature for each of saidplurality of cooling plates and/or cooling coils.

In some embodiments, the stripping system is configured to introduce gasunder pressure near the top of the crystallizer. In some embodiments,the stripping system is configured to withdraw gas near the bottom ofthe crystallizer.

In some embodiments, the system further comprises a user controlinterface in communication with the automated process control system tooperate the system.

In some embodiments, the system is automated.

In some embodiments, the system further comprises a crystal formationdetector. In some embodiments, said crystal formation detector comprisesa light source and light detector configured to detect changes in theoptical properties of material in the crystallizer. In some embodiments,said crystal formation detector comprises a heat absorption detectionsystem configured to measure the heat uptake of a cooling surface, and athermocouple configured to measure the temperature near the coolingsurface.

In some embodiments, the automated process control system is configuredto receive an identifier corresponding to a measured or estimatedI-menthol concentration in the crude mentha oil, wherein the automatedprocess control system selects crystallization conditions in thecrystallizer based, at least in part, on the identifier.

In some embodiments, the conduit is in fluid communication with astorage tank, wherein the storage tank is part of the closed system. Insome embodiments, the conduit is in fluid communication with apelletizer, wherein the pelletizer is part of the closed system.

DRAWINGS

FIG. 1 is a flow chart diagram showing an existing method for purifyingI-menthol from crude mentha oil.

FIG. 2A-B are flow charts illustrating embodiments of methods forproducing I-menthol.

FIG. 3 depicts a cross-sectional of an exemplary crystallizer in someembodiments of the system for purifying I-menthol disclosed herein.

FIG. 4A-C illustrate embodiments of a system for purifying I-menthol.

DESCRIPTION OF VARIOUS EMBODIMENTS

Various embodiments disclosed herein are generally directed towardssystems and methods for producing highly pure natural I-menthol.

At present, there are a limited number of techniques that exist forI-menthol production. A diagram of one existing I-menthol productionmethod is shown in FIG. 1. Briefly, crude mentha oil is firstcrystallized and then dementholized oils are drained away from thecrystals. The crude I-menthol crystals are then melted to form a motherliquor, which is adjusted to a desired I-menthol concentration. Themother liquor is subjected to a recrystallization step, after whichremaining dementholized oils are drained away. The remaining crystallineI-menthol is then purified and sieved to obtain an I-menthol product.

Until now, the various I-menthol production techniques have been limitedbecause they involve long production times and significant handling ofthe process materials at various stages. In particular, existing methodsfor purifying I-menthol from crude mentha oil may require two cycles ofcrystallization to isolate I-menthol from the crude mentha oilcompositions. Furthermore, adaptation of previous I-menthol productionprocesses to GMP regulation is likely to be difficult because of thehandling of process materials that is required. Another problem withprevious techniques for production of I-menthol is clumping and blockformation (“blocking”) of the solid product, which can impairpourability and handling of the I-menthol.

A new approach to production of I-menthol has been developed that allowsdirect preparation of high purity I-menthol from crude mentha oil. Inthe production process, I-menthol crystals are formed directly fromcrude oil under controlled cooling of the crude mentha oil in a closedsystem without the necessity of human contact with the crude mentha oilor I-menthol. Thus, the methods disclosed herein can be easily adaptedto GMP regulations, and may be used to produce pharmaceutical gradeI-menthol.

In one embodiment, menthol crystals can be further purified in the sameenclosed container and no recrystallization or additive to the crude oilis required to obtain highly pure I-menthol, and the method takessignificantly less time than previous I-menthol production methods.After purification, the menthol can be formed into pellets of suitablehardness and shape to prevent clumping and block formation of the solidmenthol product even in the absence of additives such as silicondioxide. In some embodiments, the I-menthol production method isentirely hands-free and can readily be adapted to meet pharmaceuticalGood Manufacturing Practices (GMP).

Some of the present embodiments involve systems useful for production ofI-menthol. For example, the systems can facilitate hands-free, automated(either partially or fully) production of highly pure I-menthol. In someembodiments, a system for production of I-menthol can include apelletizer to form I-menthol pellets for ease of handling. In someembodiments, a system for production of I-menthol can include a coolerand/or a sieve. In some embodiments, the systems can be adapted forpharmaceutical GMP.

In some embodiments, an apparatus for production of highly pure (greaterthan about 99.5%) I-menthol is provided. The apparatus may automate,regulate, and maintain temperature during crystallization of I-menthol.In one embodiment, I-menthol production can be carried out using acrystallizer that has been modified to include standard or optionalattachments. In other embodiments, I-menthol production can be carriedout using a dedicated crystallizer that has been adapted for highlycontrolled temperature regulation. In other embodiments, a system forfractional crystallization can be adapted for I-menthol production. Forexample, a fractional crystallizer (e.g., without limitation, theSulzer™ Static Crystallizer S-1) can be adapted for use in combinationwith temperature sensors, an aspiration system, a pressurized airsystem, and/or other components that aid in controlling operation of thecrystallizer.

Some of the present embodiments involve methods for producing highlypure I-menthol by crystallization using gradual cooling under controlledtemperature conditions. Using such a method, crystallization andpurification of I-menthol may be completed in less than about two weeks,compared with nearly a month for previous I-menthol production methods.Thus, certain I-menthol production methods discussed herein may reducethe time for producing pure I-menthol crystals from about two to threeweeks to about 12 or fewer days. Depending on the embodiment, productionof highly pure I-menthol using the systems and methods described hereinmay take about 12, 11, 10, 9, 8, 7, 6, 5 or fewer days. Thus, themethods can facilitate faster production of highly pure I-menthol.Furthermore, the decreased time requirements may increase overallproduction of a particular crystallization system.

As will be appreciated by one of skill in the art, the ability toquickly prepare highly pure I-menthol without handwork can have greatbenefit, especially for applications where pharmaceutical GMP isdesirable. The systems, apparatus and methods described herein allowproduction of highly pure I-menthol in a shortened period of time (i.e.,less than about two weeks) without the need for re-crystallization orhandwork.

DEFINITIONS

Unless defined otherwise, all technical and scientific terms used hereinhave the same meaning as is commonly understood by one of ordinary skillin the art. In the event that there is a plurality of definitions for aterm herein, those in this section prevail unless stated otherwise.

As used herein, “crude mentha oil” refers to oils distilled from a mintplant (Mentha species), which oils contain at least 30% I-menthol byweight, such as peppermint oil, crude peppermint oil, mint oil andmixtures thereof. “Crude mentha oil” include both “adjusted crude menthaoil” and “native crude mentha oil.”

As used herein, “dementholized oil” refers to components of crude menthaoil remaining after at least partially removing I-menthol from the oil.

As used herein, “mother liquor” is menthol-containing oil prepared forthe crystallization of I-menthol, as well as the oily liquid remainingafter crystallizing crude I-menthol.

As used herein, “native crude mentha oil” refers to mentha oil preparedby steam distillation from mentha plant material. Native crude menthaoil does not include a diluent, such as a solvent.

As used herein, “adjusted crude oil” refers to native crude mentha oilto which I-menthol and/or a diluent (e.g., dementholized oil) has beenadded, such as to adjust the I-menthol concentration.

As used herein, “automated” refers to performing, or being capable ofperforming, a method or a part of a method without manually handling ormanually moving menthol-containing materials, other than controllingoperation of an apparatus or system. As a non-limiting example, aprocess is automated when a user only presses buttons, operates knobs,or opens or closes valves to initiate various steps of a processperformed using one or more apparatuses. Automation may be controlled byone or more controllers (possibly in response to human interaction withthe controllers), such as a computing device, analog circuitry, and/ordigital circuitry. Automation may also include various sensors thatprovide feedback to a controller and/or to a human operator that may beused to automatically adjust operation of a crystallization system.

Methods

The I-menthol production methods disclosed herein can be used for directproduction of highly pure I-menthol from crude mentha oil. For example,methods disclosed herein can be used to produce I-menthol meetingpharmaceutical GMP. Production of I-menthol according to various methodsdisclosed herein may take two weeks or less. In some embodiments, themethods are performed in a closed system without human contact with thecrude mentha oil or the I-menthol.

With reference now to FIG. 2A, an exemplary method for I-mentholproduction is illustrated. Depending on the embodiment, the method ofFIG. 2A may include fewer or additional blocks and/to the blocks may beperformed in a different order than is illustrated.

Crude mentha oil is provided at block 200. The source and type of thecrude mentha oil is not particularly limited, and can be obtained, forexample, from commercial sources. The crude mentha oil can preferably beof plant origin. In some embodiments, the crude mentha oil is nativecrude mentha oil prepared by steam distillation from mentha plantmaterial. In some embodiments, the crude mentha oil is adjusted crudementha oil, where the concentration of I-menthol has been adjusted bydilution, distillation, or the addition of I-menthol.

The concentration of I-menthol in the crude mentha oil is also notparticularly limited. The crude mentha oil can, for example, includeabout 30% to about 95% I-menthol by weight (preferably about 50% toabout 90% I-menthol by weight). In some embodiments, the method includesadjusting the concentration of I-menthol in the crude mentha oil to bewithin a predetermined concentration range of I-menthol. As an example,a person of ordinary skill, guided by the teachings of the presentapplication, could identify optimal concentration ranges that improvevarious aspects of the present method (e.g., reduced crystallizationtime, greater I-menthol purity, and the like), and adjust the I-mentholconcentration to within an optimal concentration range. Alternatively,the method can be practiced using native crude mentha oil, without anyadjustment of concentration.

The crude menthol oil, in some embodiments, includes few, if any, addedorganic solvents. By avoiding the use of significant amounts of organicsolvent, the methods disclosed herein may not require additional stepsto remove organic solvents. Furthermore, the methods disclosed hereinmay be more economical compared to other methods requiring costlyorganic solvents. In some embodiments, the crude mentha oil containsless than about 30% by weight of an organic solvent. In someembodiments, the crude mentha oil is substantially free of an organicsolvent (e.g., no more than trace amounts).

Block 210 represents purifying steps for crude mentha oil performedwithin a crystallizer. Before crystallizing the I-menthol at block 214,seed crystals of I-menthol may optionally be introduced at block 212 toaid crystallization. Without being bound to any particular theory, it isbelieved that nucleation limits the crystallization kinetics ofI-menthol, and therefore adding seed crystals of I-menthol may improvethe rate of crystallization. In some embodiments, pre-formed seedcrystals of I-menthol are added to the crude mentha oil in thecrystallizer.

Seed crystals of I-menthol may also be introduced, in some embodiments,by rapidly cooling a portion of the crude mentha oil in the crystallizerto form seed crystals of I-menthol. In some embodiments, seed crystalsare formed by exposing a portion of the crude mentha oil to one or morecooling surfaces having a temperature of no more than about 20° C.(preferably no more than about 10° C., and more preferably in the rangeof about 0° C. to about 10° C.). For example, one or more coolingsurfaces within the crystallizer (e.g., plates or coils thermallycoupled to a cooling unit) can have a temperature of about 0, 1, 2, 3,4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19 or 20° C. formaking seed crystals. Typically, the seed crystals form after exposureto the surface for a few minutes, e.g., about 1, 2, 3, 4, 5, 6, 7, 8, 9,or 10 minutes (preferably 5 minutes or less). In some embodiments, afterthe seed crystals have formed, the temperature of the one or morecooling surfaces is adjusted to a crystallization starting temperatureof about 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30,31, 32, 33, 34 or 35° C. In some embodiments, seed crystals are notintroduced, and crystallization occurs at block 214 without introducingseed crystals of I-menthol.

The crude mentha oil is crystallized at block 214 to purify thematerial. As an example, the crude mentha oil is added to a crystallizerand gradually cooled to obtain crystalline I-menthol. In someembodiments, the crude menthal oil is cooled from a starting temperatureat which the I-menthol is a liquid to a cooled temperature in the rangeof about −30° C. to about 30° C. (preferably a cooled temperature in therange of about 0° C. to about 20° C.). Because the melting point ofI-menthol crystals is about 42° C., crude mentha oil above thattemperature can be expected to be in liquid form. However, because crudementha oil can also be supercooled, due to slow crystal formation,especially in the absence of seed crystals, the crude mentha oil can bea liquid, for example, at 35, 36, 37, 38, 39, 40, and 41° C., or at evenlower temperatures, all of which can be used as starting temperatures.The crude mentha oil may, in some embodiments, be cooled from a startingtemperature in the range of about 25° C. to about 45° C. (or higher)down to a cooled temperature of about 5° C. to about 15° C. In general,I-menthol crystal formation may occur over a period of about 90-140hours. Exemplary cooling conditions are provided in Example 1 below.Gradual cooling can result in formation of highly pure I-mentholcrystals within the crystallizer.

The initial crystallization temperature (e.g., at the start time of thecrystallization process, t_(c)=0) may be a temperature at which theI-menthol is a liquid. Depending on the embodiment, the initialcrystallization temperature can be, for example, about 15, 16, 17, 18,19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34 or 35°C., or a higher temperature of 36, 37, 38, 39, 40, or 41° C. In someembodiments, the initial crystallization temperature can be set basedupon the I-menthol concentration in the mentha oil starting material. Insome embodiments, the temperature within the crystallizer can beregulated by adjusting the temperature of cooling surfaces contactingthe crude mentha oil within the crystallizer. For example, thecrystallizer may include one or more plates, coils, or any othersurfaces, contacting the crude mentha oil within the crystallizer, wheresaid plates, coils, or any other surfaces are thermally coupled to acooling unit (e.g., cooled fluid is exchanged between a plate and acooling unit). In one embodiment, the various cooling surfaces (whichmay also be heating surfaces) can be independently controlled by acontroller in order to produce a desired temperature gradient in thecrystallizer.

In general, during gradual cooling for crystallization of I-menthol, thecrystallization chamber is initially cooled gradually at a rate of about0.1-10° C. during each subsequent 24 hours or so for about the first 48hours. The rate of cooling may be determined based on several factors.For example, the concentration of I-menthol in the crude mentha oil maybe used in determining the rate of cooling. In one embodiment, theconcentration of I-menthol may be determined by an I-menthol sensor thatis in communication with a controller in order to automatically setand/or adjust the rate of cooling of the crystallization chamber. Inother embodiments, the rate of cooling may be determined manually inresponse to an indicated or measured I-menthol concentration level. Inone embodiment, the initial rate of cooling is more gradual (e.g., lessthan 1 degree per day) for an I-menthol rich crude mentha oil, while theinitial rate of cooling is more rapid (e.g., about 5-10 degrees per day)for crude mentha oil with a lower concentration of I-menthol.

In one example, if the initial crystallization temperature is 25° C., atabout t_(c)=24 hours, the temperature of the crystallization chamber canbe adjusted to about 15° C.-24.9° C., depending on the determinedinitial cooling rate. For example, if the initial cooling rate is 2° C.per day, at t_(c)=24 hours the temperature would be adjusted to about23° C. In some embodiments, the temperature is adjusted at about every24 hours, e.g., the temperature is adjusted in a step-wise manner. Inthis example, using the same initial cooling rate of 2° C. per day, atabout t_(c)=48 hours, the temperature of the crystallization chamber canbe adjusted to about 21° C. As noted above, other cooling rates (more orless than 2° C. per day, including adjustments from 0.1° C. to 10° C.per day) and initial cooling periods (more or less than 48 hours) may beused. In some embodiments, the temperature is adjusted more graduallyover a period of time.

In some embodiments, after about t_(c)=48 hours, the rate of cooling thecrystallization chamber is changed from the initial cooling rate to afinal cooling rate, which may be in the range of about 1-10° C. duringeach subsequent 24 hours or so. Thus, the final cooling rate may beabout 1, 2, 3, 4, 5 or 6° C. each 24 hours or so. As noted above, thecooling rates, including the initial and final cooling rates, may beadjusted based on the concentration of I-menthol in the crude mentha oil(among other factors). Thus, for a I-menthol rich crude oil with aninitial cooling rate of 0.5° C. per day, the final cooling rate may be1-2° C. per day, while a crude mentha oil with a lower concentration ofI-menthol may have an initial cooling rate of 5° C. per day and a finalcooling rate of 6-10° C. per day. In other embodiments, the crude menthaoil is cooled at a single rate (e.g., the rate does not change from aninitial to a final cooling rate at some point in the cooling process).In one embodiment, the rate of cooling is automatically adjusted by acontroller, such as in response to sensor data indicative ofcrystallization progress within the crystallizer. In this embodiment,the rate of cooling (as well as the total cooling period) may bedifferent for each crystallization process as the controller adjusts therate in order to optimize crystallization within the crystallizer.

In some embodiments, the temperature can be adjusted about every 24hours in a step-wise manner. In other embodiments, the temperature canbe adjusted continually over a period of time, e.g., not in stepwisefashion. In general, it is preferred to reduce the temperature from astarting temperature down to a crystallization temperature in a gradualmanner, over a period of at least 24, 36, or 48 hours, and then tomaintain the temperature at a final crystallization temperature orcontinue to gradually reduce it until a desired degree ofcrystallization has occurred.

The total cooling time for the crystallization process is notparticularly limited and will vary based on several factors, such as thecooling rate(s) and the I-menthol concentration. In some embodiments,the crystallization process can be stopped at about t_(c)=100-140 hours,at which time the dementholized oil can be removed from thecrystallization chamber and the temperature of the crystallizationchamber is maintained at the final crystallization temperature, whichmay be about 5-15° C. In some embodiments, the crystallization processis stopped when the crude mentha oil reaches a temperature in the rangeof about negative 20° C. to about 15° C. (e.g., about 0, 1, 2, 3, 4, 5,6, 7, 8, 9, 10, 11, 12, 13, 14 or 15° C.). In some embodiments, thecrystallization process can be stopped at, for example, about t_(c)=120hours and the temperature within the crystallizer reaches about 10° C.In one embodiment, the total cooling time is adjusted automatically by acontrol in response to input from one or more sensors and or input froma human operator. Thus, the total cooling time may be dynamicallyadjusted for each crystallization process in order to optimizeproduction of crystal. Generally, after the crystallization process isstopped, the temperature in the crystallizer can be maintained within afew degrees of the crystallization stopping temperature.

After crystallization, the I-menthol may optionally be further purifiedin a subsequent heating block 216. The heating step includes graduallyelevating the temperature of the I-menthol crystals to aid in removal ofimpurities. Without being bound to any particular theory, it is believedthat many residual impurities within the I-menthol crystal will melt atlower temperatures than the I-menthol crystals, and that impure mixturesmelt at lower temperature than pure I-menthol. Consequently, graduallyheating the I-menthol crystals may further increase the purity of theI-menthol. In some embodiments, at the start of purification (t_(p)=0) asurface near the bottom of the crystallization chamber is adjusted to aninitial purification temperature of about 55-65° C. In otherembodiments, it is not necessary to heat a surface near the bottom ofthe crystallization chamber at the start of purification. At t_(p)=0,the crystallization chamber is generally maintained at around thecrystallization stopping temperature.

In the first few minutes of the purification process, a surface near thebottom of the crystallization chamber at an elevated temperature (ifany) can be cooled quickly to about the same temperature as in thecrystallization chamber. In some embodiments, to purify the I-menthol,the crystallization chamber can be gradually warmed to a temperature ofabout 30-40° C. In some embodiments, the crystallization chamber can begradually warmed to a temperature at which the I-menthol remains solid.In some embodiments, the temperature is regulated to change sequentiallyfrom one temperature to another. In other embodiments, the temperaturecan be adjusted in a step-wise manner every 24 hours or so. In someembodiments, the temperature of the crystallizer is adjusted to reach atemperature of about 15, 16, 17, 18, 19, 20, 21, 22, 23, 24 or 25° C. atabout t_(p)=24 hours. In some embodiments, the temperature of thecrystallizer is adjusted to reach a temperature of about 35, 36, 37, 38,39 or 40° C. at about t_(p)=48 hours. The temperature can be maintainedat about 35-40° C. until about t_(p)=70-75 hours.

In some embodiments, the heating of I-menthol can be carried out inconjunction with applying reduced or increased pressure to facilitateremoval of dementholized oil. As an example, a pressurized gas systemmay direct gas through the crystallizer to aid removal of meltedimpurities during the gradual temperature increase in the crystallizer.As another example, an aspirator can apply a vacuum to remove meltedimpurities from the crystallizer.

The dementholized oil that remains after the crystallization process isremoved at block 218. As described above, the dementholized oil includesthe remaining liquid after crystallizing the I-menthol in the crudementha oil (e.g., after the crystallization described in block 214). Insome embodiments, the dementholized oil can be removed from thecrystallizer by, for example, draining by gravity, pumping and/orpressurized fluid. For example, the dementholized oil can be removed viaa drain fluidly coupled to a dementholized oil tank.

In some embodiments, a fluid is passed over the I-menthol crystals toremove the dementholized oil from the crystals. In some embodiments, thefluid is a gas selected from air, an inert gas, and combinationsthereof. As an example, the crystallizer may include a port near the topof the crystallizer fluidly coupled to a pressurized gas system. Thepressurized gas system displaces gas, such as filtered air or nitrogen,into the crystallizer. The gas passes over the I-menthol crystals,removing oil and other impurities from the crystals, and forcesdementholized oil through a drain in the crystallizer, and optionallyinto a dementholized oil tank. Accordingly, passing a fluid over theI-menthol crystals can both improve the purity of the crystals andexpedite removing dementholized oil. In some embodiments, a reducedpressure is applied in the crystallization chamber to extract thedementholized oil. For example, an aspiration system can be fluidlycoupled to the crystallizer to form a vacuum that extracts thedementholized oil. The fluid can be a liquid, a gas, or combinationsthereof. In some embodiments, both increased and decreased pressure isapplied. For example, an aspiration system and a pressurized air systemcan be fluidly coupled to the crystallizer to force fluid through thecrystallizer. It will be appreciated that drawing fluid out of thebottom of the crystallizer and introducing fluid into the top of thechamber have similar results; that is, in both cases, fluid is caused toflow over the crystals and oil and other impurities are removed from thecrystals and moved out of the crystallizer. Note that aspiration fromthe bottom and introduction of gas into the top can be combined toenhance the removal of impurities.

After completing the steps in block 210, which may or may not includeoptional blocks 212 and/or 216, purified I-menthol crystals are obtainedat block 220. In some embodiments, the purified I-menthol crystals haveat least about 98% purity by weight (preferably at least about 99% byweight). In some embodiments, the purity of the I-menthol crystals isabout 99.4%, 99.5%, 99.6%, 99.7%, 99.8% or 99.9% by weight.

FIG. 2B illustrates a flow diagram of another embodiment of purifyingI-menthol, where various optional pre- and post-purification steps areincluded. Similar blocks shown in FIGS. 2A and 2B are numbered the same.Thus, for example, both embodiments include providing crude mentha oilat block 200. As would be appreciated by a person of ordinary skill, theoptional pre- and post-purification steps may be excluded or rearrangedwithout departing from the scope of the methods disclosed herein.

An optional filtering block 205 may be performed on the crude mentha oilprior to steps performed in the crystallizer at block 210. The filteringmay be used to remove impurities, such as particulates, using standardmeans known in the art. For example, a one micron filter can be used tofilter the crude oil that is added to a crystallizer. In someembodiments, the crude oil can be passed through a filter during loadingof the crystallizer. In some embodiments the crude mentha oil isdirectly crystallized without the optional filtration step. In someembodiments, the filtration step is automated.

After obtaining purified I-menthol at block 220, in some embodiments,the purified I-menthol can be transferred to a stock tank at optionalblock 225. Generally, for transferring the I-menthol, the crystallizercan be warmed to about 50-60° C. to melt the I-menthol crystals. Themelted I-menthol can then be transferred to, for example, a stock tank.In some embodiments, the stock tank can be connected to the crystallizerby, for example, a conduit (e.g., lines or tubing). In some embodiments,transfer of the I-menthol can be automated. Preferably, the stock tankcan be maintained at a warm temperature. In some embodiments, the stocktank includes a heating jacket to maintain the I-menthol in a fluidstate.

An optional filtering block 230 may be performed on the purifiedI-menthol. The filtering step may remove impurities, such as solids. Insome embodiments, the crude oil can be passed through a filter duringloading into a pelletizer. In some embodiments, the filtering step maybe automated.

In some embodiments, the purified I-menthol can be formed intoparticulate for ease of handling, as shown in optional block 235. Insome embodiments, solid, purified I-menthol is comminuted (e.g.,grinding, milling, cutting, etc.) into particulate. In some embodiments,the particulate are pellets. The pellets may be formed, for example,using a pelletizer, from an I-menthol melt.

The pelletizer may, in some embodiments, include a cooling mixer and apelleter. The purified I-menthol can be loaded into the cooling mixerthat is maintained at a temperature of, for example, about 10-35° C. Thetemperature of the cooling mixer can be adjusted to about 10-35° C.,preferably 15-32° C., and more preferably 17-30° C. during mixing ofI-menthol. Cooling conditions are described in more detail below. Insome embodiments, the I-menthol can be loaded into the cooling mixer by,for example, draining by gravity or pumping. The stock tank can beconnected to the cooling mixer by, for example, a conduit. In someembodiments, transfer of the I-menthol can be automated.

In general, the initial feed temperature of the I-menthol transferredinto the cooling mixer can be more than 42° C., and is preferably about55-70° C. The material feed speed, e.g., the speed at which theI-menthol is loaded into the cooling mixer, can vary depending on theamount of I-menthol prepared, the size of the cooling mixer, etc. Insome embodiments the feed speed can be about 1.0 to 3.0 kg/min. In someembodiments, the material feed speed can be, for example, about 1, 1.5or 2 kg/min. In some embodiments, the rotation speed of the coolingmixer can be, for example, about 10, 11, 12, 13, 14, 15, 16, 17, 18, 19,20, 21, 22, 23, 24, 25, 26, 27, 28, 29 or 30 rpm. In one embodiment, thematerial feed speed can be about 1.5 kg/min and the rotation speed ofthe cooling mixer can be about 20 rpm.

Because the melting point of I-menthol is about 42° C., under cooledmixing conditions, the I-menthol is changed to a solid state and forms asherbet-like slurry. In some embodiments, the mixing time can be, forexample, about 0.5-10 minutes, and is preferably about 1-2 minutes.

In some embodiments, a cooling mixer can include, for example, a rotorand a jacket for regulating temperature of the cooling mixer. In someembodiments, the temperature of the cooling mixer can be regulated byadjusting the temperature at, for example, the rotor inlet, the rotoroutlet, the jacket inlet and/or the jacket outlet. For preparation ofthe I-menthol slurry, exemplary temperature conditions are set forth inTable 1 below. Columns labeled 1-6 (indicated in first row of Table 1)provide six different exemplary pelletizing conditions for preparationof I-menthol pellets having good hardness and good, non-heterogeneousshape.

TABLE 1 Cooling Material Mixer Feed Rotor Rotor Jacket Jacket ConditionTemp. Inlet Outlet Inlet Outlet No. (° C.) (° C.) (° C.) (° C.) (° C.) 158 11 12 31 32 2 58 6 8 31 32 3 58 10 11 31 32 4 60 9 11 30 32 5 60 9 1130 32 6 60 15 17 15 17

After the I-menthol slurry is formed, the slurry can be extruded intolong strands by the pelleter. In some embodiments, the I-menthol can beformed into strands by, for example, being pushed out through narrowholes of the pelleter. As a result, noodle-like strands of I-menthol canbe formed. The I-menthol strands can be cut or broken into desiredsizes. The diameter of the pellets can vary and will depend on the sizeof the pelleter holes. In some embodiments, the pellets can have adiameter of about 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16,17, 18, 19 or 20 mm. In preferred embodiments, the pellets can have adiameter of about 3, 5 or 7 mm.

As shown in optional block 240, in some embodiments, the I-menthol canbe cooled. The cooler serves to harden the I-menthol and may optionallyremove low-boiling impurities. For example, pellets of I-menthol can betransferred from the pelletizer to a cooler. Any suitable means forcooling the I-menthol pellets may be used, such as a refrigerated andventilated chamber or other cooling apparatus. In some embodiments, theI-menthol pellets can be transferred to the cooler by, for example, aconveyer belt. The conveyer belt can be enclosed to prevent foreigncontaminants from contacting the I-menthol. In some embodiments,transfer of the I-menthol can be automated.

In some embodiments, the cooler can be equipped with, for example, acool air supply system and/or a mesh tray. In some embodiments, cold aircan be supplied from the bottom of the cooler. The mesh tray can bevibrated, thereby agitating and floating the I-menthol pellets tofacilitate solidification.

In optional block 245, the cooled I-menthol can be transferred from thecooler to a sieve. The I-menthol can be sieved to remove small particlesfrom the dried I-menthol. For example, I-menthol pellets may be sievedto remove particles below a predetermined size. In some embodiments, theI-menthol pellets can be transferred to the sieve by, for example, aconveyer belt. The conveyer belt can be enclosed to prevent foreigncontaminants from contacting the I-menthol. In some embodiments,transfer of the I-menthol can be automated. Any suitable sieve can beused to sieve the I-menthol particulate, and various sieves arecommercially available. In generally, the openings in the sieve aresized to retain particulates having the desired size and allow smallerpieces to be removed.

The I-menthol pellets can be packaged into packing containers forshipping or storage, as shown in optional block 250. In someembodiments, the I-menthol can be transferred by, for example, aconveyer belt. The conveyer belt can be enclosed to prevent foreigncontaminants from contacting the I-menthol. In some embodiments,transfer of the I-menthol into packing containers can be automated.

Systems and Apparatus

Some of the present embodiments involve a system and apparatus usefulfor production of highly pure I-menthol. In some embodiments, thesystems can automate temperature regulation during I-menthol production.To accomplish temperature control for production of highly pureI-menthol crystals, the system can include a crystallizer that receivescrude mentha oil. The crystallizer includes heating and coolingstructures, such as, for example without limitation, plates, coils,plate-coils, or any other suitable device, which provide surfaces forI-menthol crystal nucleation and growth. In some embodiments, the systemforms a closed system that prevents contact between the content of theclosed system and outside contaminants.

With reference now to FIG. 3, an exemplary system for purifyingI-menthol is illustrated. In the embodiment shown in FIG. 3, thecrystallizer 300 comprises heating/cooling plates 305, but in otherembodiments the crystallizer 300 may comprise alternative and/oradditional heating and/or cooling devices. The plates 305 can be anysize and shape for providing a suitable surface for growth of I-mentholcrystals and are located in the crystallizer 300. Crude mentha oil canbe added directly into the crystallizer (the crystallization chamber).When crude mentha oil is added to the crystallizer, it comes intocontact with plates 305. In some embodiments, the structure of theheating/cooling plates 305 can be, for example without limitation, flatplates, coils, radiator-like coils, etc. In some embodiments, plates 305are plate-coils set closely together (e.g., about 2.5 to about 10 cmbetween each plate). Generally, plates 305 can precisely control thetemperature inside the crystallizer 300, such as in response to controlsignals from a controller.

In the embodiment of FIG. 3, conduits 310 connect the plates 310 to aheating/cooling unit (e.g., as illustrated by in FIG. 4A by cooling unit410 and heating unit 415). As an example, fluid enters plates 305through conduits 310, and then the fluid circulates back to aheating/cooling unit. The temperature of plates 305 is controlled byheating or cooling the circulating fluid. In some embodiments, plates305 are thermally coupled to a heating/cooling unit. In someembodiments, the temperature of each of plates 305 can be independentlycontrolled. For example, each plate may receive separately circulatedfluids that can have different temperatures. In some embodiments, thetemperature of the bottom and the side walls in the chamber can beindependently controlled by another heating or cooling unit.

The temperature of crystallizer 300 can be controlled for production ofhighly pure I-menthol crystals, as described above with respect tomethods of purifying I-menthol. The temperature of plates 305 incrystallizer 300 may also be adjusted to a desired temperature. In someembodiments, the temperature of the one or more plates of thecrystallizer can each be adjusted to different temperatures (e.g., inresponse to control signals from a controller and/or from a humanoperator). In some embodiments, all the plates of the crystallizer canbe the same temperature In some embodiments, one or more plates 305 inthe crystallizer 300 can include one or more temperatures sensors 307.

In some embodiments, plates 305 of crystallizer 300 can include acooling/heating medium for regulating temperature. As used herein“cooling/heating medium” refers to a medium that can be used to regulatetemperature, including cooling and heating. For example, media such as,for example without limitation, solvents or refrigerants, cryogenicsubstances or other suitable substances can be added to thecooling/heating device for regulating temperature.

Various ports may be included in the crystallizer to exchange materialin the crystallizer. The crystallizer may optionally include drain 312configured for removing liquid from the crystallizer. In someembodiments, drain 312 is fluidly coupled to an aspiration unit (e.g.,as illustrated in FIG. 4B by aspiration system 425) to withdraw liquidfrom the crystallizer. In some embodiments, drain 312 may be used forremoving liquid from the crystallizer. The crystallizer may also includeport 315 for directing a fluid into the crystallizer. For example, apressurized gas system (e.g., as illustrated in FIG. 4A by pressurizedair system 420) may be fluidly coupled to port 315, and pressurized aircan be forced into the crystallizer through this port 315. As discussedabove, the pressurized air can force dementholized oil off of thecrystals and out of the crystallizer through drain 312.

FIG. 4A illustrates another embodiment of the system for purifyingI-menthol. In some embodiments, the system for I-menthol production canbe controlled by user defined processing parameters via automatedprocess control system 400 (hereinafter “controller”). Depending on theembodiment, controller 400 may comprise one or more computing systems,such as a desktop, notebook, or portable computing device; or integratedcircuits, such as field programmable gate arrays (FPGAs), applicationspecific integrated circuits (ASICs), microcontrollers, or proprietarylogic circuits. In one embodiment, controller 400 comprises (and/or isin communication with) one or more input devices, such as a touchscreen,mouse, or keyboard, and one or more output devices, such as a monitor ordisplay of a mobile device, so that the controller may displayinformation regarding the status of the I-menthol production system toan operator of the system and receive control instructions from theoperator. With the use of controller 400, the system can be partially orfully automated for I-menthol production, including automation oftemperature control, air pressure control, aspiration, draining, mixing,transport of I-menthol, pelleting, drying, sieving and packing with userdefined processing parameters. In some embodiments, the system can beprogrammable for desired time periods and temperature settings foroptimal I-menthol production. The system can also be programmable forpressure settings, moisture control settings, vapor evacuation, sampleloading, etc. In some embodiments, controller 400 can include a programstorage function. In other embodiments, the system can be controlledmanually by user input at each stage in production. In some embodiments,the system can include safeguards for accommodating problems which mayarise during processing such as, for example, exceeding desiredtemperature ranges, pressure or leakage problems, power failures, etc.

In some embodiments, controller 400 is in communication withcrystallizer 405 (e.g., as illustrated in FIG. 3 by crystallizer 300)and can be used to regulate the temperature in crystallizer 405. Forexample, controller 400 can be programmed to increase and decrease thetemperature of the various parts of the crystallizer (e.g.,heating/cooling plates) as desired. In some embodiments, temperaturesensors (e.g., as illustrated in FIG. 3 by temperature sensors 307) forheating/cooling surfaces of the crystallizer can provide temperaturedata to the controller. In some embodiments, the data from thetemperature sensors can be used to adjust temperature of the variousparts of the crystallizer.

Controller 400 may be in communication with cooling unit 410 and heatingunit 415. As discussed above, cooling unit 410 and heating unit 415 maybe thermally coupled to the crystallizer. For example, fluid may beexchanged between heating/cooing units and plates within thecrystallizer. Thus, in some embodiments, the control may regulate thetemperature within the crystallizer by controlling operation of coolingunit 410 and heating unit 415, which are thermally coupled to thecrystallizer. Crystallizer 405, cooling unit 410 and heating unit 415may, in some embodiments, form a single unit in communication withcontroller 400.

In some embodiments, controller 400 comprises a processor programmed(e.g., executing software code stored on a computer readable medium,such as a memory (RAM, ROM, Flash memory, etc.), a hard drive, and/oroptical storage medium of the controller) to automate any of the methodsfor purifying I-menthol disclosed above. For example, the processor maybe programmed to crystallize the crude mentha oil by automaticallyreducing and maintaining temperatures as described for crystallizationblock 214 in FIG. 2A. As another example, the processor may beprogrammed to perform any of the tasks performed within the crystallizer(e.g., any of the steps within block 210 in FIG. 2A). The processor maybe programmed, in some embodiments, to gradually reduce the temperatureof crude mentha oil in the crystallizer from a temperature at which thecrude mentha oil is a liquid to a temperature below 30° C. in a gradualmanner over a period of at least 8 hours to cause I-menthol crystals toform in the crystallizer. In some embodiments, the processor may beprogrammed to heat and/or melt the purified I-menthol crystal afterdementholized oil has been removed from the crystallizer. In someembodiments, the processor is programmed to heat the I-menthol crystalsgradually to a temperature below 40° C. to remove impurities from thecrystals.

The controller 400, in some embodiments, selects conditions forcrystallizing the I-menthol (e.g., temperature, cooling rate, etc.), atleast in part, based upon a received identifier that corresponds to theI-menthol concentration in the crude mentha oil. For example, controller400 may be in communication with optional sensor 417 that determines theI-menthol concentration. After receiving the I-menthol concentration,controller 400 may select appropriate crystallizing conditions. Asanother example, a user may enter the concentration at a user interfacein communication with controller 400.

In some embodiments, the system may include an optional crystal detector419 that is configured to detect the presence of I-menthol crystalswithin the crystallizer. Controller 400 can be in communication with thecrystal detector to identify when crystals have formed and the degree ofcrystallization in the crystallizer. In some embodiments, the controllerincludes a processor configured to lower the temperature in thecrystallizer to suitable conditions for seed crystal formation (e.g.,conditions for introducing seed crystals at block 212 in FIG. 2A). Onceseed crystals are detected by the seed crystal detector, controller 400may adjust the temperature to a temperature suitable for crystallization(e.g., conditions suitable for crystallization block 214 in FIG. 2A).Once the system detects the presence of sufficient crystals to indicatethat crystallization has completed to the desired degree, thedementholized oil can be removed from the crystallizer, under eithermanual or automatic control.

In some embodiments, the seed crystal detector comprises a light sourceand a light detector configured to detect changes in the opticalproperties of material in the crystallizer. Thus, for example,crystallized I-menthol may exhibit higher light scattering compared toliquid crude mentha oil, which may be detected. In some embodiments, theoptional crystal detector comprises a detector in the cooling circuitconfigured to measure heat removal by a cooling surface, and athermocouple configured to measure the temperature near the coolingsurface. As an example, the relationship between the heat removal andtemperature may be used to detect crystallization. Note thatcrystallization releases heat, so that while crystallization isoccurring, heat energy is removed from the crude mentha oil without thesame decrease in temperature in the crystallizer as would occur if nocrystallization were occurring.

The system can include a pressurized air or gas system 420 to aid inremoval of dementholized oil from crystals. For example, duringpurification of I-menthol crystals, pressurized air system 420 canprovide pressurized gas to the chamber of the crystallizer to facilitateremoval of dementholized oil from the surface of I-menthol crystals. Thecontroller 400 may be in communication with pressurized air system 420and may control applying pressurized air at an appropriate time in theprocess (e.g., at extraction block 218 in FIG. 2A).

FIG. 4B illustrates another embodiment of a system disclosed herein.Similar components to those in FIG. 4A are numbered the same (e.g.,FIGS. 4A and 4B both have crystallizer 405). The system includes anaspiration system 425 fluidly coupled to crystallizer 400. As describedabove, the aspiration system may be used to reduce the pressure in thecrystallizer and extract dementholized oil. In some embodiments,controller 400 is in communication with aspiration system 425 to applyreduced pressure at an appropriate time (e.g., at extraction block 218in FIG. 2A). In some embodiments, the system includes both pressurizedair system 420 and aspiration system 425.

As used herein, a “stripping system” refers to any components configuredto aid removal of dementholized oil by adjusting the pressure. Thus, astripping system is a broad term that would include pressurized airsystem 420, aspiration system 425, and combinations thereof.

FIG. 4C illustrates another embodiment of a purification system havingvarious optional components. Similar components to those in FIGS. 4A and4B are numbered the same (e.g., FIGS. 4A, 4B and 4C all havecrystallizer 405). As would be appreciated by a person of ordinaryskill, various optional components may be excluded or rearranged withoutdeparting from the scope of the present invention.

In some embodiments, the system can include dementholized oil tank 430for storage of dementholized oil tank that has been removed from thecrystallizer. For example, after crystallization, the dementholized oiltank can be pumped or drained from the crystallizer into dementholizedoil tank 430 (e.g., at extraction block 218 illustrated in FIG. 2A).Transfer of the dementholized oil from the crystallizer to thedementholized oil tank 430 can be automated.

In some embodiments, the system can include a stock tank 435 for storageof I-menthol that has been removed from the crystallizer. For example,after purification (e.g., at block 220 in FIGS. 2A and 2B), theI-menthol crystals in crystallizer 400 can be melted and pumped ordrained from the crystallizer chamber into stock tank 435 (e.g., asillustrated in block 225 in FIG. 2B). Preferably, stock tank 435 isconnected to the crystallizer via a conduit. In some embodiments, stocktank include a heating unit to maintain the I-menthol at a temperatureat which the I-menthol is a liquid. The transfer of the I-menthol fromcrystallizer 400 to the stock tank 435 can be automated.

In some embodiments, the system can include pelletizer 440 for shapingthe I-menthol into pellets for ease of handling (e.g., as illustrated informing particulate block 235 in FIG. 2B). As described above,pelletizer 440 may include a cooling mixer for mixing the menthol priorto pellet formation. Depending on the embodiment, the cooling mixer maycomprise a proprietary cooling mixer, such as a mixer that is integrallycoupled with a pelleter, and/or a commercially available cooling mixer(e.g., the Krimoto, Ltd. SC Processor model number SCP-100, and others).In some embodiments, pelletizer 440 can be connected to stock tank 435or to the crystallizer via a conduit for hands-free transfer of liquidI-menthol to the cooling mixer. In some embodiments, controller 400 isin communication with pelletizer 440. The transfer of the I-menthol fromthe stock tank or the crystallizer to the cooling mixer can beautomated.

The temperature of the cooling mixer can be regulated to ensure that theI-menthol is at the correct temperature for forming pellets having thedesired hardness, shape, air content, etc. In some embodiments, purifiedI-menthol can be loaded into the cooling mixer. The purified I-mentholis typically loaded into the cooling mixer in liquid form. In general,the initial feed temperature of the I-menthol is about 45-65° C. Thecooling mixer can be equipped with, for example, a cooling jacket thatcan regulate the temperature of the cooling mixer. Generally, thetemperature of the cooling mixer can be maintained between about 5 toabout 40° C. during, for example, mixing of the I-menthol for pelletformation.

Pelletizer 440 may further include a pelleter. In some embodiments, thepelleter can include a plate having holes through which solidified,sherbet-consistency I-menthol can be extruded through and shaped into anoodle-like form. In some embodiments, the I-menthol can be pushed by,for example, means of a rotating screw inside the pelleter. The mentholtransfer speed can be changed by the rotation speed. I-Menthol isextruded through the holes of the plate, forming long, noodle-likestrands. The size of the holes of the plate can vary depending on thedesired pellet size, and is not meant to be limited to any particularsize. In some embodiments, the holes can have a diameter of, forexample, about 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16,17, 18, 19 or 20 mm. Pelleters are commercially available and include,for example without limitation, the Dulton Corp. Pelleter Double modelnumber EKDFJ-100. The pelletizer may also include a cutter configured tocut the strands into desired lengths. As an example, the cutter may be arotating blade that cuts the extruded strands at predetermined timeintervals.

In some embodiments, the I-menthol production system includes cooler 445for cooling the I-menthol pellets (e.g., as illustrated in cooling block240 in FIG. 2B). In some embodiments, the pellets can be transferredfrom pelletizer 440 to the cooler 445 by, for example, an enclosedconveyer belt. Transfer of the I-menthol from the pelletizer 440 to thecooler 445 can be automated. Generally, cooler 445 includes cooled airflow to aid hardening of the I-menthol. In some embodiments, the cooler445 can include, for example, vibrating mesh platforms for agitation ofthe pellets and facilitating solidification of the I-menthol.Preferably, the cooler is enclosed to prevent contaminants fromcontacting the I-menthol. In addition, filters can be used inconjunction with the dryer to ensure that the air flowing over theI-menthol pellets is clean and pure. In some embodiments, drying of theI-menthol pellets can be automated, such as by control signals fromcontroller 400.

In some embodiments, the I-menthol production system includes sieve 450.Sieve 450 can be used to remove small particles from the dried I-mentholpellets (e.g., as illustrated by sieving block 245 in FIG. 2B). In someembodiments, the pellets can be transferred from the dryer to the sieveby, for example, an enclosed conveyer belt. Preferably, sieve 450 isenclosed to prevent contaminants from contacting the I-menthol. In someembodiments, sieving of the I-menthol pellets can be automated, such asby control signals from controller 450.

In some embodiments, the I-menthol production system includes packingcontainers 455 for packaging the I-menthol. For example, a conveyer beltor other conveyer (e.g., pneumatic conveyer, screw conveyer) from thesieve 450 can be used to transfer I-menthol pellets from sieve 450 topacking containers 455. In some embodiments, the conveyer belt can beenclosed to prevent contaminants from contacting the I-menthol. In someembodiments, packaging of the I-menthol can be automated. In someembodiments, the packaging containers are fluidly connected to stocktank 435. Liquid I-menthol may be directly loaded into packingcontainers 455, and the I-menthol cooled to a solid within thecontainers.

In some embodiments, controller 400 executes computer software thatcontrols the various parameters for I-menthol production. In someembodiments, the software accepts user input for each factor, forexample, temperature, air pressure, aspiration, drainage, transport,mixing, pelleting, drying, sieving, and packing. In this manner,I-menthol production can be automated. In some embodiments, the softwareperforms any of the methods described herein.

EXAMPLES

Aspects of the present teachings can be further understood in light ofthe following examples, which should not be construed as limiting thescope of the present teachings in any way.

Example 1

This example illustrates possible methods for production of I-mentholhaving a purity of 99.6% or greater.

Crude mentha oil (I-menthol purity of about 80%) was transferred fromdrums to a crystallizer through a one micron filter. The crystallizerincluded cooling plates on which I-menthol crystals could nucleate andgrow. I-Menthol crystals were formed by slow, step-wise cooling of thecrystallization chamber from about 25° C. down to about 10° C. overabout a 120 hour period, then maintaining the chamber temperature atabout 10° C. for about 24 hours. Table 2 shows the temperature of thesides, bottom and cooling plate of the crystallization chamber atvarious time points during the crystallization process. At then end ofabout 120 hours, highly pure I-menthol crystals were formed on theplates of the crystallizer.

TABLE 2 Temperature (degree Centigrade) Sides of Bottom of Cooling TimeChamber Chamber Plates 0 30 30 10 5 min. 25 25 25 24 hr. 23 23 23 48 hr.21 21 21 72 hr. 16 16 16 96 hr. 10 10 10 120 hr. Stop

After crystallization, the dementholized oil was drained by gravity fromthe bottom of the crystallizer into a separate tank.

After removal of the dementholized oil, I-menthol crystals were purifiedwhile still in the crystallization chamber. The I-menthol purificationprocess was carried out using aspiration and gradual heating of theI-menthol crystals. The bottom valve of the crystallizer was opened, andaspiration was started. The temperature of the crystallization chamberwas gradually increased to about 35° C. over about a 48 hour timeperiod, and the I-menthol was maintained at about 35° C. for about 2 to4 hours. Temperature conditions for the sides, bottom and cooling platesof the crystallizer are provided below in Table 3.

TABLE 3 Temperature (degree Centigrade) Sides of Bottom of Cooling TimeChamber Chamber Plates 0 10 60 10 5 min. 10 10 10 24 hr. 20 20 20 48 hr.35 35 35 72 hr. Stop

After purification, the I-menthol was removed from the crystallizer byheating the crystallization chamber to about 60° C. to melt theI-menthol crystals. The sides, bottom and cooling plates of thecrystallization chamber were heated to about 60° C. After about 5 hours,the bottom valve of the crystallizer was connected to a stock tank, andthe melted I-menthol was transferred to the stock tank. The purifiedI-menthol had a purity of about 99.6%.

Example 2

This example illustrates possible methods for I-menthol pelletizationand cooling.

The highly pure I-menthol produced by the method described in Example 1was formed into pellets for ease of handling. A pelletizer including acooling mixer and pelleter was used. The I-menthol was transferred fromthe stock tank to the cooling mixer of a pelletizer at a rate of about200 kg/hr. In the cooling mixer, the I-menthol was mixed at about 15° C.for minutes to form a sherbet-like slurry.

Pellets were formed by extruding the I-menthol slurry through thepelleter and cutting the resulting I-menthol strands into desiredlengths. The pelleter outlet was maintained at about 5° C. The pelletswere transferred to a dryer and dried using an air flow speed of about0.9 cubic meters per minute at about 25° C.

Example 3

This example illustrates a preliminary study to determine pelletizationconditions using a cooling mixer and pelleter.

The highly pure I-menthol produced by the method described in Example 1was formed into pellets using a variety of different conditions todetermine the conditions suitable for preparing I-menthol tablets havinggood hardness and good shape. Conditions used and results from eighteendifferent pelletization experiments are summarized in Tables 4 and 5below. The I-menthol was transferred from the stock tank to the coolingmixer of a pelletizer at a rate of about 1.5 kg/hr. In the coolingmixer, the I-menthol was mixed under the conditions shown to form aslurry. The I-menthol slurry was formed into long strands and cut intodesired lengths.

TABLE 4 Exp. No. 01 02 03 04 05 06 07 08 09 cooling mixer: Material feedtemp (° C.) 58 58 58 58 60 60 60 60 65 Material feed speed (kg/min) 1.51.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 Rotor inlet temp (° C.) 11 6 4 10 4 8 911 8 Rotor outlet temp (° C.) 12 8 7 11 10 11 13 13 9 Jacket inlet temp(° C.) 31 31 4 31 30 30 30 30 30 Jacket outlet temp (° C.) 32 32 7 32 3232 32 32 32 Rotation speed (rpm) 20 20 20 20 20 20 20 20 20 pelleter:Rotation speed (rpm) 60 60 60 60 60 60 60 60 60 Hole diameter (mm) 5 5 55 5 5 5 5 5 Results: Pellet hardness (G = good, G G G G H H G S S H =too hard, S = too soft) Pellet shape (G = good, G G H G H H G G G H =heterogeneous)

TABLE 5 Exp. No. 10 11 12 13 14 15 16 17 18 cooling mixer: Material feedtemp (° C.) 58 58 58 58 60 60 60 60 65 Material feed speed (kg/min) 1.51.5 1.5 1.5 1.5 1.5 1.5 1.5 1.5 Rotor inlet temp (° C.) 9 9 10 11 15 1715 15 15 Rotor outlet temp (° C.) 11 11 12 13 17 19 17 17 17 Jacketinlet temp (° C.) 30 30 30 11 15 17 15 15 15 Jacket outlet temp (° C.)32 32 32 13 17 19 17 17 17 Rotation speed (rpm) 20 20 20 20 20 20 20 2020 pelleter: Rotation speed (rpm) 60 60 60 60 60 60 60 60 60 Holediameter (mm) 5 5 5 5 5 5 3 5 7 Results: Pellet hardness (G = good, G HH H G S G G G H = too hard, S = too soft) Pellet shape (G = good, G H HH G G G G G H = heterogeneous)

Results from the eighteen experiments shown in Tables 4 and 5demonstrate that depending on the conditions used during pelletization,the pellet hardness and shape can vary. The pelletization conditionsused in experiments 01, 02, 04, 07, 10, 14, 16, 17 and 18 resulted inpellets having both good hardness and good, non-heterogeneous shape.

It is to be understood that both the foregoing general description andthe detailed description are exemplary and explanatory only and are notrestrictive of the invention, as claimed. In this application, the useof the singular includes the plural unless specifically statedotherwise. In this application, the word “a” or “an” means “at leastone” unless specifically stated otherwise. In this application, the useof “or” means “and/or” unless stated otherwise. Furthermore, the use ofthe term “including,” as well as other forms, such as “includes” and“included,” is not limiting. Also, terms such as “element” or“component” encompass both elements or components comprising one unitand elements or components that comprise more than one unit unlessspecifically stated otherwise.

The section headings used herein are for organizational purposes onlyand are not to be construed as limiting the described subject matter inany way.

It will be appreciated that there can be an implied “about” prior to thetemperatures, concentrations, times, etc. discussed in the presentteachings, such that slight and insubstantial deviations are within thescope of the present teachings herein. Also, the use of “comprise”,“comprises”, “comprising”, “contain”, “contains”, “containing”,“include”, “includes”, and “including” are not intended to be limiting.It is to be understood that both the foregoing general description anddetailed description are exemplary and explanatory only and are notrestrictive of the invention.

INCORPORATION BY REFERENCE

All references cited herein, including patents, patent applications,papers, text books, and the like, and the references cited therein, tothe extent that they are not already, are hereby incorporated byreference in their entirety. In the event that one or more of theincorporated literature and similar materials differs from orcontradicts this application; including but not limited to definedterms, term usage, described techniques, or the like, this applicationcontrols.

EQUIVALENTS

The foregoing description and Examples detail certain preferredembodiments of the invention and describes the best mode contemplated bythe inventors. It will be appreciated, however, that no matter howdetailed the foregoing may appear in text, the invention may bepracticed in many ways and the invention should be construed inaccordance with the appended claims and any equivalents thereof.

What is claimed is:
 1. A system for purifying I-menthol, comprising: acrystallizer containing crude mentha oil of plant origin; a strippingsystem adapted to pass a gas through the crystallizer; an automatedprocess control system comprising a processor programmed to: initiatereduction of a temperature in the crystallizer in order to reduce thetemperature of the crude mentha oil from a temperature at which thecrude mentha oil is a liquid to a temperature below 30° C. in a gradualmanner over a period of at least 8 hours to cause I-menthol crystals toform in the crystallizer; activate the stripping system in order to passthe gas over the crystals in the crystallizer to remove liquid from thecrystals; and initiate heating of the crystallizer in order to melt thecrystals; and a conduit configured to receive melted I-menthol from thecrystallizer, wherein the crystallizer and the conduit together comprisea closed system that prevents contact between the content of the closedsystem and outside contaminants.
 2. The system of claim 1, wherein thecrystallizer comprises a plurality of cooling plates and/or coolingcoils.
 3. The system of claim 2, wherein the automated process controlsystem independently controls the temperature for each of said pluralityof cooling plates and/or cooling coils.
 4. The system of claim 1,wherein the system is automated.
 5. The system of claim 1, furthercomprising a crystal formation detector.
 6. The system of claim 1,wherein the conduit is in fluid communication with a storage tank,wherein the storage tank is part of the closed system.
 7. The system ofclaim 1, wherein the conduit is in fluid communication with apelletizer, wherein the pelletizer is part of the closed system.